KR20150053444A - Explosion-Proof LED lamp - Google Patents

Abstract

The present invention relates to an explosion-proof lamp using an LED and, more particularly, to an explosion-proof LED lamp which includes a junction box which is installed on a ceiling or a wall, a power supply unit which is attached to or detached from the junction box, a body which has a plurality of holes to pass air and a heat radiation piece between the holes and is attached to or detached from the junction box or the power supply unit, the LED which is installed on the inner side of the body, a heat sink which is arranged between the body and the LED, is closely attached to the inner side of the body and the LED, and discharges heat from the LED, and a window cover which is mounted on the body and isolates the LED from the outside. The LED receives the power from the power supply unit. If the heat is generated from the LED, the generated heat is discharged through the heat sink. The heat discharged through the heat sink is transmitted to the body. If the air is inputted to the hole of the body, the heat radiation piece guides the inputted air and the inputted air cools the heat transmitted to the body. Thereby, the junction box is easily installed on a ceiling. The power supply unit is freely arranged according to an installation space. Heat dissipation with high efficiency is implemented.

Description

Explode-Proof LED lamp,

More particularly, the present invention relates to an LED explosion-proof which is capable of freely placing a power supply, is easy to attach and detach from a ceiling, and can be quickly cooled by air flowing to the periphery.

In general, the area where dangerous atmosphere is formed by flammable gas and vapor or dust, or a factory which treats various flammable materials is a region where there is always danger.

These dangerous areas are classified into NEC (National Electric Code) or IEC (International Electro-technical Committe) according to the dangerous status and classified into 0, 1 and 2 kinds of hazardous places. And Type 1 places are always subject to fire, explosion and heat hazards, and the electrical appliances used are usually designed to have an explosion-proof structure.

On the other hand, the explosive gas can penetrate into a small gap generated by the expansion and contraction caused by blinking of the lighting apparatus, so that it is difficult to obtain the effect of explosion-proof even if the apparatus is closed.

Therefore, the explosion-proof lamp is a lamp in which inert gas is introduced into the surroundings so as not to be ignited even if an explosive gas penetrates into the interior of the apparatus. Generally, such explosion-proof lamps use incandescent lamps, fluorescent lamps, There is a problem that the size is large and power consumption is large.

In particular, when a discharge lamp such as a fluorescent lamp is used as a light source, explosion-proof lamps use a ballast to control an overcurrent, which is bulky and consumes a large amount of electric power. It is also exposed to unstable conditions.

In addition, when the light source and the stabilizer are not properly heat-dissipated, such an explosion-proof lamp has a problem that it can shorten its life due to overheating and cause a very dangerous situation.

Therefore, such an explosion-proof lamp usually has a lamp having a glass bulb such as a high-pressure mercury lamp or a high-pressure sodium lamp, or a metal halide lamp, and has a pressure-resistant casing for preventing explosion of the lamp from secondary explosion in the event of spark due to overheating do.

The pressure-resistant casing has an internal pressure that the container can withstand when the explosive gas or steam explodes due to an electric spark or the like of the lamp in the inside of the container. The pressure-resistant casing has airtightness .

Further, the casing such as explosion-proof casing is formed into a structure in which a glass globe or a tempered glass is tightly bonded to a casing body made of a metal material, and a protective net is formed outside the glass globe or the tempered glass.

Further, since the lamp is provided with a glass bulb, it is necessary to secure a sufficient inner space for the glass globe or the tempered glass to accommodate the glass bulb and to have an internal pressure against the breaking force at the time of explosion of the glass bulb, The entire casing including the glass is made of a thick and bulky explosive structure having a large size.

In such a conventional technique, lamps emit light due to their heat emission characteristics, so that sparks due to heat frequently occur, so lamp replacement is frequent, and when a lamp is replaced, a casing having a heavy structure must be opened or closed. There was a very difficult problem.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide an LED explosion-proof which can realize a high efficiency heat radiation performance without restriction of installation space.

In order to achieve the above object,

A power supply unit detachably attached to the junction box unit, a plurality of holes through which air passes, and a heat dissipation piece formed between the holes and the holes, A light emitting diode (LED) unit disposed inside the body, a light emitting diode (LED) unit disposed between the body and the LED unit and closely contacting the inner surface of the body and the LED unit, And a window cover unit mounted on the body and blocking the LED unit from the outside, wherein the LED unit receives power from the power supply unit, generates heat from the LED unit, The generated heat is discharged through the heat sink portion, and the heat discharged through the heat sink portion is transmitted to the body And, when the air into the hole in the body is achieved by a LED, comprising a step of the heat dissipation side of the inlet and guiding the inlet air to cool the air to the heat transfer to the explosion-proof body.

The junction box may further include a sealing bracket coupled to the junction box part to easily install the junction box part on the ceiling or the wall surface.

In addition,

The power supply unit and the body may be detachably attached to the first connection unit.

In the power supply unit,

And at least three second connection portions connected to at least one of the first connection portion and the body on an outer surface thereof, the first connection portion and the second connection portion being disposed between the junction box portion and the body to connect the junction box portion and the body in a line, The power supply unit can be installed in the periphery of the junction box unit by being rotated laterally or longitudinally according to the space.

In addition, the sealing bracket may be formed in a cross shape.

In addition,

In order to maximize the thermal efficiency, a COB (Chip On Board) type LED module may be included.

According to the present invention, the air due to the convection phenomenon is allowed to flow along the heat radiating piece while passing through the hole of the body, thereby maximizing the cooling performance of the body.

Further, by using a COB type LED module, the heat generated by the LED can be well transmitted to the heat sink, thereby realizing a highly efficient heat radiation performance.

In addition, the power supply unit can be freely disposed according to the installation space, and the installation space can be restricted.

In addition, the junction box can be easily installed on the ceiling by installing the sealing bracket first on the ceiling and then installing the junction box on the sealing bracket.

1 is a perspective view of an LED explosion-proof lamp according to an embodiment of the present invention;
2 is a perspective view of an LED explosion-proof lamp according to an embodiment of the present invention viewed from the bottom;
3 is a front view of an LED explosion-proof lamp according to an embodiment of the present invention;
4 is a front view of an LED explosion-proof lamp according to an embodiment of the present invention.
5 is a front view of a part of the body of the present invention.
6 to 8 are front views showing an example in which the positions of the power supply units are arranged differently in the present invention.
9 and 10 are front views illustrating an example in which the power supply unit is omitted in the present invention.

The preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, in which the technical parts already known will be omitted or compressed for the sake of brevity.

1 to 8, an LED explosion-proof lamp according to an embodiment of the present invention includes a junction box unit 1, a power supply unit 2, a body 3, an LED (light-emitting diode) A heat sink portion 4, and a window cover portion 6. [0028] As shown in Fig. Here, it further includes a sealing bracket 7.

The junction box portion 1 has a substantially rectangular parallelepiped support portion 11 which is screwed to a sealing bracket 7 to be described later and has a plurality of screw holes 111 penetrating upward and downward at the upper end of the support portion 11 And a lower portion of the housing 12 is formed with a first connecting portion 121 having an opening at one end thereof. The junction box portion 1 has a through hole 112 formed in the protruded surface of the support portion 11 so as to protrude from one side of the front and rear left and right sides thereof, The second cover 14 and the second cover 14 are formed with the first connection part 141 having one opening. The through hole 112 is a hole through which the main power source (AC 220V) is drawn into the explosion-proof luminaire from four directions.

A switching power supply (SMPS) unit 2 converts an AC power source to a DC power source and supplies the DC power source to an LED unit 5 to be described later. The power source unit 2 is formed in a substantially rectangular parallelepiped shape, Three or more second connecting portions 21 are formed on the upper surface, the bottom surface and the side surface, and a cap 22 is provided on the second connecting portion 21 which is not used. The power supply unit 2 is installed so as to be connected to the junction box unit 1. One end of the nipple 8 is inserted into the second connection portion 21 of the power supply portion 2 and the other end of the nipple 8 is connected to the first connection portion 121 or 141 of the junction box portion 1 The power supply unit 2 and the junction box unit 1 are connected.

Accordingly, the user selects the position of the power supply unit 2 according to the installation environment, and installs the position of the power supply unit 2 in the junction box unit 1. For example, if the front and rear right and left sides are narrow spaces, the power supply unit 2 can only be installed from the bottom of the junction box. However, in other circumstances, mounting the power supply unit 2 on the side surface of the junction box increases the coupling strength. And it is possible to prevent collision with other devices by forming the projecting length to be short. At this time, in order to minimize the protrusion of the power supply unit 2 to the side, the power supply unit 2 may be rotated and vertically installed.

The body (3) has a substantially disk shape, a lower end is opened, and one region is opened so that a joint (9) is installed at the upper end. A plurality of holes (32) The heat dissipating piece 31 is radially formed.

The body 3 is provided with a joint 9 at the upper opening and one end of the nipple 8 is attached to the joint 9 and the other end of the nipple 8 is connected to the lower end of the junction box 1 Is inserted into the first connection part (121) formed and connected to the junction box part (1). Herein, the joint 9 may be a known joint 9 which can be used to tilt the body 3 in relation to the joint 9, and the joint 9 used therein may be a detailed A description thereof will be omitted.

The power supply unit 2 is installed at the lower end of the junction box unit 1 and then the nipple 8 is inserted into the second connection unit 21 of the power supply unit 2, . Accordingly, the junction box portion 1, the power supply portion 2, and the body 3 can be connected in a row so that the present invention can be installed in a long space, narrow in front, rear, left and right, and up and down.

The heat sink portion 4 radiates heat generated in the LED portion 5 to be described later so that a large number of heat sinks 41 protrude from the upper surface of the disk, (3). The heat sink portion 4 is formed so as to correspond to the inner surface of the body 3 so that the shape of the heat sink 41 adheres to the inner surface of the body 3. The heat generated by the LED 5 can be quickly transmitted to the body 3 through the heat sink 4 by closely contacting the heat sink 4 with the inner surface of the body 3. [

The LED unit 5 is inserted into the body 3 through the lower end opening of the body 3 and a COB (Chip On Board) type LED module is used to maximize the heat radiation efficiency. The heat sink unit 4).

Accordingly, by using a COB (Chip On Board) type LED module, the heat generated in the LED unit 5 can be quickly transferred to the heat sink unit 4 to maximize the heat radiation efficiency of the heat sink unit 4. [ . The COB (Chip On Board) type LED module uses a well-known product, and a detailed description thereof will be omitted.

The window cover portion 6 includes a transparent panel 61 and a fixing portion 62.

The transparent panel 61 is formed of transparent glass or synthetic resin in a substantially disc shape, is fitted to the fixing portion 62, and is fixed to the lower end opening of the body 3.

The fixing portion 62 is provided with the fixing portion 62 and the fixing portion 62 in such a manner that the transparent panel 61 is inserted into the fixing portion 62 in order to fix the transparent panel 61 to the body 3, (3). At this time, the fixing portion 62 is coupled in a rotating manner so as to be easily detached from the body 3. Here, the technique in which the fixing portion 62 is detachably attached to the body 3 in a rotational manner is well known in the art, and thus a detailed description thereof will be omitted.

The ceiling bracket 7 is provided on the ceiling. The ceiling bracket 7 is formed in a substantially "X" shape with a coupling hole 71 at its center and a female screw 72 at its end. For example, the screw is inserted into the engagement hole 71 of the sealing bracket 7 to fix the sealing bracket 7 to the ceiling, and then the screw is screwed into the screw hole 111 of the junction box part 1, The junction box portion 1 can be fixed to the ceiling bracket 7 by inserting it into the female screw 72 of the joint box 1.

More specifically, since the sealing bracket 7 is formed in the shape of "X ", the contact area between the ceiling and the junction box part 1 can be minimized, and even if there is a predetermined bend in the ceiling scene, (7), so that the ceiling bracket (7) can be easily installed on the curved ceiling, so that the junction box part (1) can be easily installed on the ceiling.

The junction box portion 1, the power supply portion 2, and the body 3 described above can be formed of duralumin to increase the strength and reduce the weight.

When an LED module (not shown) using an AC power source is used, the power supply unit 2 may be omitted and only the junction box unit 1 and the junction box unit 1 may be used.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

When the power supply is supplied and the LED unit 5 is operated, heat is generated in the LED unit 5.

Heat generated in the LED unit 5 is transmitted to the body 3 through the heat sink unit 4. [

Heat transmitted to the body 3 through the heat sink 4 is dissipated to the outside through the body 3 and the heat dissipating piece 31.

For example, when the air passes through a plurality of holes formed in the periphery of the body 3, the air passing through the hole is blocked by the heat dissipating piece 31 and passes through the heat dissipating piece 31 Flows on the outer surface of the body 3 and flows upward. At this time, the flowing air takes heat generated from the outer surface of the heat dissipating piece 31 and the body 3 to cool the body 3. That is, by forming a hole penetrating up and down around the body 3, air can easily circulate around the body 3, and the circulating air is guided by the heat dissipating piece 31, So that the body 3 can be cooled quickly.

In addition, by using a COB (Chip On Board) type LED module, heat generated in the LED unit 5 can be quickly transmitted to the heat sink unit 4, thereby preventing the LED unit 5 from being overheated.

In describing the present invention described above, the same reference numerals are used for the same configurations even if the embodiments are different, and the description thereof may be omitted if necessary.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Shall not be construed as being understood. Therefore, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. The present invention is not limited thereto.

One; Junction box section
11; Support
111; Screw hole
112; Through hole
12; housing
121, 141; The first connection portion
13; The first cover
14; The second cover
2; Power supply unit
21; The second connection portion
3; Body
31; Heat radiating piece
32; hole
4; Heat sink part
41; Heat sink
5; LED
6; Window cover portion
61; Transparent panel
62; [0035]
7; Sealing bracket
71; Joining ball
72; female screw
8; nipple
9; Joint

Claims (6)

JUNCTION BOX installed on ceiling or wall;
A power supply unit detachably attached to the junction box unit;
A body formed with a plurality of holes through which air passes, a heat dissipating piece formed between the holes and the holes, and detachably attached to the junction box portion or the power supply portion;
An LED disposed inside the body;
A heat sink unit disposed between the body and the LED unit and closely contacting the inner surface of the body and the LED unit to emit heat generated in the LED unit; And
And a window cover portion mounted on the body and shielding the LED portion from the outside,
The LED unit receives power from the power supply unit, heat generated when heat is generated from the LED unit is discharged through the heat sink unit, heat radiated through the heat sink unit is transmitted to the body, Wherein when the air is introduced into the hole, the introduced air guides the introduced air to cool the heat transferred to the body.
The method according to claim 1,
And a sealing bracket coupled to the junction box part to easily install the junction box part on the ceiling or the wall surface.
The method according to claim 1,
The junction box unit may include:
Wherein the power supply unit and the body are detachably attached to the first connection unit, wherein the power supply unit and the body are detachably attached to the first connection unit.
The method of claim 3,
Wherein the power supply unit includes at least three second connection units connected to at least one of the first connection unit and the body,
Wherein the junction box portion and the body are arranged in a line between the junction box portion and the body, or are installed horizontally or vertically around the junction box portion according to an installation space.
3. The method of claim 2,
And the sealing bracket is formed in a cross shape.
The method according to claim 1,
[0027]
And an LED explosion-proof lamp including a COB (Chip On Board) type LED module for maximizing heat radiation efficiency.

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